KR102152738B1 - Wearable Device for Disaster Safety Management and Safety Management System Using the Same - Google Patents

Abstract

The present invention provides a preemptive and efficient response to the initial disaster situation by providing real-time guidance on disaster risk factors to workers while wearing it on the user's body in various industrial environments, and by monitoring the disaster situation in the work site in real time, A device body formed to be wearable on a specific body part of a user to provide efficient management of field safety; 5 types of detection sensors are configured to be installed detachably on the main body of the device and sense the surrounding harmful gas, but detect at least one of oxygen and carbon dioxide, carbon monoxide, hydrogen sulfide, and ammonia to measure the amount of gas detection, and the detection sensor A sensor module configured to be selectively applicable; A communication module configured to transmit data sensed from the sensor module or to receive data from an external device; And a main control module that connects the sensor module and the communication module to enable operation, and analyzes whether there is a danger situation based on the sensing data input from the sensor module, wherein the main control module includes It provides a wearable device for disaster safety management including a smart firmware that automatically recognizes a detection sensor that has been replaced among five different detection sensors so that it can be implemented by itself.

Description

Wearable Device for Disaster Safety Management and Safety Management System Using the Same}

The present invention relates to a wearable device for disaster safety management and a safety management system using the same.More specifically, in various industrial environments, the present invention provides information on disaster risk factors to workers in real time while wearing them on the user's body to preemptively preempt the initial situation of a disaster. The present invention relates to a wearable device for disaster safety management, and a safety management system using the same, capable of efficiently managing site safety in a disaster situation by monitoring a disaster situation within a work site in real time by responding effectively and effectively.

In general, as a method for safety management of work in industrial sites such as construction or manufacturing and work sites such as underground spaces or enclosed spaces, safety training to ensure that workers wear hard hats and become familiar with dangerous places, etc. Safety is managed from various disaster situations by monitoring safety from the manager through the surveillance camera installed inside.

However, there is a limit in that all workers in the field cannot be monitored throughout the work only with the structure of the monitoring functional system that manages safety in the field using a surveillance camera, and the relationship between the equipment and workers in the field or other risks that cannot be confirmed with the naked eye. There was a limitation that the safety management efficiency according to the disaster was insufficient because the factors could not be accurately identified.

As a prior art disclosed in order to overcome the technical limitations as described above, Korean Patent Application Publication No. 101385 (2017.09.06.) uses a wearable device that is linked to the worker's smart phone and is worn by the worker only during working hours. The wearable device measures the worker's status information (heart rate, movement) and sends it at regular intervals (set according to the job site characteristics, such as 5 to 10 minutes). When compared with the stored worker's basic information (health checkup record, heart rate measured before work, etc.), if it exceeds or decreases by a certain number, if there is no movement of the worker for a certain period of time, the information is not received for a certain period of time (more than 30 minutes). When not working, a warning sound is sent to the monitoring manager and the monitoring manager checks the health status and location of the worker in real time, allowing real-time confirmation of the worker's safety accident in the office. A work monitoring system using a wearable device and a smart phone app is known.

However, in the case of the prior art described above, since the manager simply monitors the safety situation of the worker and checks only the presence or absence of a safety accident, there is a problem that it is difficult to respond preemptively because the worker who is exposed to the dangerous situation in the site cannot check the disaster situation at all. there was.

In addition, the above-described conventional technology recognizes a disaster risk situation due to the leakage of harmful gases, because it is difficult to identify a disaster situation in which various types of toxic gases used in industry and work sites are leaked with the naked eye of not only managers but also workers in the site. It is difficult to do, and there is a problem that safety accidents such as loss of consciousness or often life as workers are exposed to the disaster environment caused by gas leakage cannot be prevented.

KR Patent Publication No. 10-2017-0101385 (2017.09.06.)

The present invention is to solve the above problems, and the operator is configured to guide disaster information including harmful gas detection information to a wearable type device that can be directly worn by the operator, while the operator directly recognizes the disaster situation in the field in real time. A wearable device for disaster safety management and a safety management system using the same, which promotes the preemptive response of workers, prevents safety accidents by recognizing the leakage of harmful gases that are difficult to visually check, and speeds up response due to disasters. It has a purpose.

In addition, the present invention is configured with a detachable structure that can selectively use sensors for each detection item according to the work situation for each site, so that a clear detection efficiency for each harmful gas can be achieved and at the same time, for disaster safety management that can increase the work safety of workers. It is to provide a wearable device and a safety management system using the same.

A wearable device for disaster safety management proposed by the present invention includes a device body formed to be wearable on a specific body part of a user; 5 types of detection sensors are configured to be detachably installed on the device body and detect the surrounding harmful gas, but detect at least one of oxygen and carbon dioxide, carbon monoxide, hydrogen sulfide, and ammonia to measure the amount of gas detection, and the detection sensor A sensor module configured to be selectively applicable; A communication module configured to transmit data sensed from the sensor module or to receive data from an external device; And a main control module that connects the sensor module and the communication module to enable operation, and analyzes whether there is a danger situation based on the sensing data input from the sensor module, wherein the main control module includes It includes a smart firmware that automatically recognizes a detection sensor that has been replaced among five different detection sensors so that it can be implemented by itself.

In addition, a GPS receiver installed in the device body and configured to receive location information of a user in the field is provided.

The device body includes a human body detection sensor that detects whether a user is moving and transmits it to the main control module, and a timer that measures the time in connection with the body detection sensor or measures the time from an external input signal and transmits it to the main control module. Configure.

In the main control module, when a detection signal indicating no movement of the user is transmitted from the human body detection sensor, the time is measured from the timer, and after 30 seconds have elapsed, a text message is sent through the communication module.

In the main control module, when the gas detection amount measured by the sensor module exceeds the reference set amount of the harmful gas, a warning sound and a warning sound that can be checked by a user are output and a text message is sent through the communication module.

The main control module is configured to output a warning light and a warning sound that can be checked by the user when the time exceeds the time set by the user's working time from the timer and simultaneously send a text message through the communication module.

In addition, a safety management system using a wearable device for managing difficulty safety proposed by the present invention includes a wearable device for disaster safety management as described above; And a management server unit that transmits and receives a data signal with the wearable device, receives a signal from the wearable device, and processes information related to a field worker in real time so that an administrator can monitor it in real time.

According to the wearable device for disaster safety management according to the present invention and the safety management system using the same, various types of harmful gases are flexibly applied to each site and detected, and disaster information is provided to workers as well as managers in real time. Through this, it is possible to secure the safety of the people scientifically and to minimize the time and economic loss caused by damage through rapid response. Furthermore, since the tasks that were artificially performed for the safety and safety management of workers are efficiently automated, it is possible to reduce labor costs by seeking changes in the work environment.

In addition, the wearable device for disaster safety management according to the present invention and the safety management system using the same enable the manager as well as workers in the field to efficiently respond to the on-site dangerous situation, enabling a leading response of the government's new paradigm to industrial accidents, It has the effect of identifying the direct and indirect causes of accidents and promoting prevention through big data analysis in the future.

1 is a perspective view schematically showing an embodiment of a wearable device for disaster safety management according to the present invention.
Figure 2 is a block diagram schematically showing an embodiment of a wearable device for disaster safety management according to the present invention.
3 is a block diagram schematically showing an embodiment of a safety management system using a wearable device for disaster safety management according to the present invention.
4 is a block diagram schematically showing a response scenario in an embodiment of a safety management system using a wearable device for disaster safety management according to the present invention.

The present invention comprises a device body formed to be wearable on a specific body part of a user; 5 types of detection sensors are configured to be detachably installed on the device body and detect the surrounding harmful gas, but detect at least one of oxygen and carbon dioxide, carbon monoxide, hydrogen sulfide, and ammonia to measure the amount of gas detection, and the detection sensor A sensor module configured to be selectively applicable; A communication module configured to transmit data sensed from the sensor module or to receive data from an external device; And a main control module that connects the sensor module and the communication module to enable operation, and analyzes whether there is a danger situation based on the sensing data input from the sensor module, wherein the main control module includes It features a wearable device for disaster safety management, including a smart firmware that automatically recognizes a detection sensor that has been replaced and applied among five different detection sensors so that it can be implemented by itself.

In addition, the present invention includes a wearable device for disaster safety management as described above; Using a wearable device for disaster safety management including; a management server unit that transmits and receives a data signal with the wearable device, receives a signal from the wearable device, and processes information related to field workers to be monitored in real time by an administrator. The safety management system is a feature of the technology configuration.

Next, a preferred embodiment of a wearable device for disaster safety management according to the present invention will be described in detail with reference to the drawings.

However, in the embodiments described below, the illustration and description have been omitted except for essential parts in describing the present invention, and the same reference numerals are assigned to the same and similar components throughout the specification, and detailed descriptions thereof are omitted. do.

First, an embodiment of the wearable device 100 for disaster safety management according to the present invention is as shown in Figs. 1 and 2, the device body 110, the sensor module 120, the communication module 130 and , Comprises a main control module 140.

The device body 110 is a structure that can be worn on a specific body part of the user, and various types of fixing clips (not shown in the drawing) to be worn on the user's belt or shoulder strap at the outer rear of the device body 110 It is formed to have.

The device body 110 is provided with a plurality of operation buttons 111 capable of operating various functions from a user, and on one surface of the device body 110, it is possible to check various information related to surrounding dangerous situations including harmful gas information. A display 113 is provided.

The operation button 111 includes an information confirmation button 111a for checking various information through the display 113, an emergency call button 111b for transmitting a call signal to the manager in a crisis situation that the user can recognize, and , And a timer button 111c for setting and driving the following timer 127 configuration.

The device body 110 includes a warning lamp 117 and a warning speaker 118 to warn the user to be able to check with the naked eye and sound by a signal detected in a dangerous situation.

Although not shown in the drawing, the device body 110 includes an internal battery that supplies power for driving.

The built-in battery is capable of charging power that can be operated for about 4 to 6 hours in the field, and the device body 110 has a charging port 119 that can be connected to a charger so that the built-in battery can be recharged at any time. do.

The device body 110 is equipped with a GPS receiver 115, a human body detection sensor 125, and a timer 127.

The GPS receiver 115 is installed in the device body 110 and configured to receive location information of a user in the field. That is, the GPS receiver 115 continuously receives GPS location information to determine the movement line of a worker in case of an emergency, and to seek quick rescue, and quick tracking and action are possible.

The human body detection sensor 125 detects whether the user is moving and transmits a detection signal to the main control module 140.

The human body detection sensor 125 includes a gyro sensor for measuring an inclined angular velocity during the user's movement to determine whether there is an accident or not, and the human body detection sensor 125 is used to detect the user's movement during movement. It is equipped with an acceleration sensor to measure the corresponding acceleration to determine whether the user is moving due to an accident.

When the human body detection sensor 125 is configured as described above, it is possible for the user to quickly respond to falls and suffocation accidents during work.

The timer 127 measures a time in conjunction with the human body sensor 125. That is, when the human body sensor 125 detects an abnormality in the user's movement, the timer 127 is driven to measure the time.

The timer 127 is configured to measure time from an external input signal, that is, an input signal according to an operation of the timer button 111c.

The time is measured by the timer 127 and transmitted to the main control module 140 when a set time has elapsed, and the warning lamp 117 and the warning speaker 118 together with the warning lamp 117 and the warning speaker 118 through the main control module 140 The display 113 is interlocked to apply an output signal.

In addition, the device body 110 may be configured to include a camera module (C) so as to obtain image information along a movement path of a user in the field.

The camera module (C) is configured by being applied integrally on the device body 110 or separately from the device body 110, but is always connected to the device body 110 by wire or wireless It is composed of a structure that can acquire.

In the above, it is preferable to apply WiFi direct, which can be easily connected without a separate wireless access point, between devices located adjacent to the camera module (C) and the device body 110, since mutually smooth and simple communication can be connected. .

When the camera module (C) is configured as described above, real-time and detailed monitoring of the site situation is possible by the manager, thereby enabling more proactive response to disasters.

The sensor module 120 performs a function of detecting surrounding harmful gases that may leak in the site.

The sensor module 120 is configured in the form of a block-type cartridge and is detachably installed on the device body 110 in a structure that can be combined and separated freely.

The sensor module 120 is configured to be capable of measuring a corresponding gas detection amount while detecting at least one harmful gas of oxygen, carbon dioxide, carbon monoxide, hydrogen sulfide, and ammonia. That is, the sensor module 120 includes five types of detection sensors 121 such as an oxygen sensor, a carbon dioxide sensor, a carbon monoxide sensor, a hydrogen sulfide sensor, and an ammonia sensor.

The sensor module 120 is a configuration that can intensively detect each harmful gas by using five types of detection sensors 121 (oxygen sensor, carbon dioxide sensor, carbon monoxide sensor, hydrogen sulfide sensor, and ammonia sensor). 5 types of detection sensors 121 that are separated from each other according to the dangerous gas are configured to be selectively applicable.

In the sensor module 120, the five types of detection sensors 121 are each applied in the form of a micro sensor, and the sensor module 120 is a connector (RS232) that can be connected to establish a connection state with the main control module 140. ) (Not shown in the drawings).

The communication module 130 has a structure capable of connecting to a communication device such as a monitoring system of an administrator or a smartphone as well as communication connection with the camera module (C).

The communication module 130 is configured to transmit data sensed from the sensor module 120 or to receive data from an external device.

Since the communication module 130 applies Wi-Fi and LTE wireless communication interfaces to smoothly transmit and receive data and actively cope with changes in the field work environment, real-time information leakage may not occur.

In addition, the device body 110 is configured to enable a voice call by accessing a telephone network and an IP network through the communication module 130.

The main control module 140 performs a function of controlling all driveable components applied to the present invention to be connected in a lump so that they can be driven in conjunction with each other.

The main control module 140 is provided with a smart firmware 145 that classifies the detection sensors 121 of the sensor module 120 by type and enables automatic recognition.

The smart firmware 145 is an intelligent structure, and a detection sensor that is applied to a replacement among five different detection sensors 121 (oxygen sensor, carbon dioxide sensor, carbon monoxide sensor, hydrogen sulfide sensor, ammonia sensor) of the sensor module 120 ( 121) is automatically recognized so that it can be implemented by itself.

For example, when the oxygen sensor is separated from the sensor module 120 to which the oxygen sensor and the carbon monoxide sensor are applied and then replaced with a hydrogen sulfide sensor, the smart firmware 145 of the main control module 140 recognizes itself. Implement the function.

The main control module 140 connects and controls the sensor module 120 and the communication module 130, respectively, to enable operation, and analyzes whether there is a danger situation based on the sensing data input from the sensor module 120. .

The main control module 140 basically classifies three types (no user movement, exceeds the reference value of harmful gas leakage, and exceeds the working time) and transmits the disaster situation to the user and the manager.

In the case of the main control module 140, when the detection signal for the movement of the user in the field does not respond, a detection signal indicating that there is no movement of the user from the human body detection sensor 125 is sent to the main control module 140. When delivered, the main control module 140 transmits a control signal to the timer 127 to drive the timer 127, and when a signal after 30 seconds is input by measuring the time from the timer 127 After the main control module 140 determines that it is a disaster situation, it is configured to send a text message to the administrator through the communication module 130.

In the main control module 140, when the measured value of leakage of harmful gas around the site exceeds the reference value set by the Industrial Safety Management Corporation, after detecting various types of harmful gas from the sensor module 120, the main control module ( 140), when it is determined that the measured gas detection amount of the harmful gas exceeds the reference setting amount of the harmful gas, the main control module 140 sends a control signal to the warning lamp 117 and the warning speaker 118. It is configured to output a warning light and a warning sound to confirm that the user is in a crisis situation by authorization, and to send a text message from the main control module 140 to the administrator through the communication module 130.

In the main control module 140, when a field worker, who is a user, exceeds a set working time in the field, after setting and inputting a standard working time required for the corresponding work to the main control module 140, the timer 127 When the time set as the user's working time is counted and input to the main control module 140 as exceeding the set time from the timer 127, the warning lamp 117 and the warning lamp 117 and A control signal is applied to the warning speaker 118 to output a warning light and a warning sound that a user can check, and the main control module 140 is configured to send a text message to the administrator through the communication module 130.

Next, a safety management system using a wearable device for disaster safety management according to the present invention configured as described above will be described.

First, an embodiment of a safety management system using a wearable device for disaster safety management according to the present invention includes a wearable device 100 and a management server unit 200 as shown in FIGS. 3 and 4.

For the wearable device 100, the device body 110, the sensor module 120, the communication module 130, the main control module 140, and the like are composed of main components. ), the configuration of the embodiment is applied in the same manner, so a detailed description thereof will be omitted.

The management server unit 200 transmits and receives a data signal mutually with the wearable device 100, and various data information (image information, sensor measurement information, sensor detection information, location information, etc.) received from the wearable device 100 Builds a distinct database by storing the information list and date separately.

The management server unit 200 receives a signal from the wearable device 100 and processes information related to a field worker so that an administrator can monitor it in real time.

The management server unit 200 is a structure capable of receiving signals from the wearable device 100 and displaying corresponding information in a form that can be checked by an administrator, and is designed to be suitable for a large-capacity big data environment, and collects large-capacity data. After analyzing the log, the result of the log analysis is displayed in a structured GUI (graphic user interface) screen.

The management server unit 200 monitors site information in real time and collects and stores the information in a database format, and then collects and manages data of various field situations such as detection and measurement of harmful gases, images, and accident history. Organize to promote information search through.

The management server unit 200 aims to analyze a dangerous situation based on input existing information such as a real-time field situation and sensor data. For example, based on the various data collected on the management server unit 200, the work is performed in what environment (sensor, video, etc.), in what environment the accident is triggered, and how it was processed after the accident. And it is configured to be analyzed by schedule and condition.

Since the management server unit 200 is configured with a VoIP gateway (VG) and a SIP server (S) to enable a call with an administrator through the voice call function of the wearable device 100, the telephone network and IP address of the wearable device 100 After connecting the network, it relays the call connection with the administrator's IP phone.

That is, according to the wearable device for disaster safety management according to the present invention configured as described above and the safety management system using the same, various types of harmful gases are flexibly applied to each site and detected, and disaster information is provided to workers as well as managers in real time. Therefore, it is possible to scientifically secure the safety of the public through a preemptive response, and to minimize the time and economic loss caused by damage through a rapid response. Furthermore, it is possible to reduce labor costs by seeking changes in the work environment because the work that was artificially performed for the safety and safety management of workers is efficiently automated.

In addition, the wearable device for disaster safety management according to the present invention and the safety management system using the same enable the manager as well as workers in the field to efficiently respond to the on-site dangerous situation, enabling a leading response of the government's new paradigm to industrial accidents, It is possible to identify the direct and indirect causes of accidents and prevent them in advance through big data analysis in the future.

In the above, a wearable device for disaster safety management according to the present invention and a preferred embodiment of a safety management system using the same have been exemplarily described, but the present invention is not limited thereto, and the scope of the claims, specification, and accompanying drawings It is possible to carry out various modifications within, and this also falls within the scope of the present invention.

100: wearable device 110: device body
111: operation button 113: display
115: GPS receiver 117: warning lamp
118: warning speaker 119: charging port
120: sensor module 121: detection sensor
125: human body detection sensor 127: timer
130: communication module 140: main control module
145: smart firmware 200: management server unit

Claims (7)

A device body 110 formed to be wearable on a specific body part of the user;
It is installed on the device body 110 so as to be detachably installed and configures five kinds of detection sensors that detect the surrounding harmful gas, but detect at least one of oxygen and carbon dioxide, carbon monoxide, hydrogen sulfide, and ammonia to measure the amount of gas detection, and A sensor module 120 configured to selectively apply the detection sensor;
A communication module 130 configured to transmit data sensed from the sensor module 120 or receive data from an external device;
A main control module 140 which connects the sensor module 120 and the communication module 130 to enable operation, and analyzes whether there is a danger situation based on the sensing data input from the sensor module 120; Include,
The main control module 140 includes a smart firmware that automatically recognizes a detection sensor that has been replaced among the five different detection sensors 121 of the sensor module 120 so that it can be implemented by itself,
The device body 110 has a structure that can be worn on a specific body part of the user, and has a fixing clip at the outer rear of the device body 110 so that it can be worn on a belt or shoulder strap of the user,
The device body 110 includes a GPS receiver 115 configured to receive location information of a user in the field, and a human body detection sensor 125 that detects whether the user is moving and transmits it to the main control module 140. Wow, a timer 127 that measures a time in connection with the human body sensor 125 or measures a time from an external input signal and transmits the measured time to the main control module 140, and a plurality of operation buttons that can be operated by a user ( 111), and a display 113 that can check information related to the surrounding dangerous situation including harmful gas information,
The human body detection sensor 125 includes a gyro sensor that measures an inclined angular velocity during the user's movement, and an acceleration sensor that measures an acceleration according to the movement of the user,
The operation button 111 includes an information confirmation button 111a for checking information through the display 113, an emergency call button 111b for transmitting a call signal to an administrator in a crisis situation that a user can recognize, and the timer. A timer button 111c for setting and driving 127 is provided,
The sensor module 120 is configured in the form of a block-type cartridge that can be combined and separated on the device body 110,
In the main control module 140, when a detection signal notifying that there is no movement of the user is transmitted from the human body sensor 125, the communication module 130 measures the time from the timer 127 and after 30 seconds elapses. Disaster text messages are sent through
In the main control module 140, when the gas detection amount measured from the sensor module 120 exceeds the reference set amount of the harmful gas, a warning light and a warning sound that can be checked by the user are output and at the same time, through the communication module 130 It is made to send disaster messages,
The main control module 140 outputs a warning light and a warning sound that can be checked by the user when it exceeds the time set by the user's working time from the timer 127 and sends a warning text through the communication module 130 at the same time. Wearable device for safety management. delete delete delete delete delete delete

Images